KR20070053344A - Capillary ion chromatography - Google Patents

Abstract

The present invention provides a flow-through ion exchange packing in a housing; And a suppressor comprising a capillary tubing 32 consisting of a selective permeable ion exchange membrane, wherein the capillary tubing is at least partially positioned in the ion exchange packing. The apparatus of the present invention also includes a circulation conduit 38 for circulating an aqueous liquid from the detector 34 to the packing. In addition, the capillary tubing may have weakly acidic or weakly basic functionality. The present invention also provides a method of using the device.

Capillary, Ion Chromatography, Suppressor

Description

Capillary Column Ion Chromatography {CAPILLARY ION CHROMATOGRAPHY}

The present invention relates to an apparatus for capillary ion chromatography, and a method of using the capillary ion chromatography.

Ion chromatography (IC) has been widely used as an analytical technique for determining anionic and cationic analytes in various sample matrices since its introduction in 1975. Today ion chromatography is performed in a variety of separation and detection methods. In the detection of suppressed conductivity, ion chromatography is the most commonly used form of technique. Upon detection of the suppressed conductivity, the conductivity of the target analyte is improved by converting the eluent into a form having weak conductivity by an eluent suppression device (called a "suppressor"). Early suppressors were columns filled with ion exchange resins in the appropriate ion form. Such a packed-bed suppressor has a problem that a dead volume is relatively large and chemical regeneration is required offline. To solve this problem, suppressors based on ion exchange fibers and other membranes have been developed. Such suppressors can be continuously regenerated, using either acid or base regenerant solutions.

One disadvantage of conventional membrane suppressors is the conventional use of an external source of acid or base regenerant solution to continuously regenerate the suppressor. In order to solve the problem of chemically regenerated membrane suppressors, a variety of designs, such as those described in US Pat. Nos. 4,999,098, 5,248,426, 5,352,360, and 6,325,976, have been developed for a long time. Electrolytically regenerated membrane suppressors have been developed. Such an electrolytic suppressor has several advantages for use for ion chromatography. In the case of using an electrolytic suppressor, it is possible to continuously and simultaneously suppress the eluent, to regenerate the suppression medium, and to provide a suppression capacity that can be used for a conventional IC. The electrolytic suppressor is easy to operate because it can electrolytically generate regenerant ions using the eluent or water which has been pressed. Thus, there is no need to prepare a regenerant solution off-line. In addition, the electrolytic suppressor is suitable for performing gradient separation. The electrolytic suppressor has a significantly low suppression area volume, thus achieving high chromatographic separation efficiency.

In ion chromatography, a dilute solution of an acid, a base, or a salt is usually used as the chromatography eluent. Conventionally, these eluents were diluted using reagent grade chemicals and prepared offline. Offline preparation of chromatographic eluates takes a long time, is prone to operator error, and in some cases contaminants may be introduced. For example, dilute NaOH solution (widely used as eluent in the separation of anions by ion chromatography) is easily contaminated by carbonate. Since carbonate may be introduced as an impurity from the reactants and may be introduced by adsorption of carbon dioxide in the air, it is difficult to prepare a NaOH eluate containing no carbonate. The presence of carbonate in the NaOH eluate can degrade the performance of ion chromatography, and during the hydroxide gradient, chromatographic baseline drift can occur, even the target analyte. Reproducibility of the retention time may not be obtained. Recently, several methods have been studied that utilize the charge selective electromigration of ions through electrolysis of water and ion exchange media for the purification or regeneration of high purity ion chromatography eluates. U.S. Pat.Nos. 6,036,921, 6,225,129, 6,316,271, 6,316,270, 6,315,954, and 6,682,701 are electrolytics that can be used to regenerate high purity acid and base solutions using water as a carrier. The device is described. In the case of using such an apparatus, a high purity acid or base solution containing no impurities can be automatically regenerated and used as an eluent in chromatographic separation. This arrangement simplifies the gradient separation that can be performed using a current gradient with minimal delay effect instead of using a conventional mechanical gradient pump.

By using both an electrolytic eluent generator and a suppressor, it is possible to drastically change the conventional operating method of the ion chromatography method, and improve the separation performance of various ion chromatography using only deionized water as the mobile phase. Can be. Using these electrolytic devices, the performance of ion chromatography can be improved by minimizing baseline rise during gradients, increasing retention time reproducibility, lowering detection background, and lower detection limits for target analytes. It can greatly improve.

In recent years, due to the simplification of the separation process, the popularity of capillary high performance liquid chromatography using a separation column having an internal diameter (I.D.) of 1 mm or less as an analytical separation means is increasing. Separation columns used for ion chromatography typically have a column inner diameter of 2 mm to 4 mm and are operated at a flow rate of 0.2 to 3 mL / min. When ion chromatography is performed on a capillary column (ie using a small bore column with an internal diameter of about 1 mm or less), there are potentially many advantages in the analysis of ionic analytes. When using a capillary separation column, separation efficiency and / or speed can be improved. Since a much smaller amount of sample is used when the separation process is performed on the capillary column, it is more suitable for use where the amount of sample is limited. Because capillary ion chromatography systems are typically operated at 1-20 μl / min, the amount of eluent consumed is quite small. Capillary ion chromatography exhibits improved performance in continuous operation at minimal time intervals, thereby minimizing problems associated with system startup and shutdown. When the capillary ion chromatography is operated at a low flow rate, the system affinity with the mass spectrometer is improved. In addition, when ion chromatography is performed on a capillary type column, it can be used as a non-performing application using a new column filled with a stationary phase that is more unfamiliar and difficult to prepare.

Ion chromatography is slower to develop in terms of simplification of separation process compared to high performance liquid chromatography. To date, research in the field of capillary ion chromatography using suppressed conductivity detectors has not varied. In 1983, Rokushika and colleagues reported on a capillary ion chromatography system using a suppressed conductivity detector ( J. Chromatography , 260 (1983) 81-88). According to their studies, anion exchange capillary columns were prepared by charging surface aggregated anion exchange resins. The suppressor is prepared using the Nafion ^® tubing, hollow fiber (hollow fiber tubing), 0.05 using eau room benzenesulfonyl external solution (external solution) of the acid having the M is regenerated chemically. There is a document described on the separation of inorganic anions and carboxylic acids. In 1997, Dasgupta and colleagues reported on the performance of a capillary ion chromatography system using an online high pressure electrolytic sodium hydroxide eluent generator. In this system, sodium hydroxide eluate is used as a carrier for electrolytic generation at a flow rate of 2 μl / min. Typically, deionized water is used, and a capillary column filled with anion exchanger is used as a separation column. been manufactured using ^® tubing, a suppressor that plays a chemical is used by using a sulfuric acid solution. On the other hand, there is a document described for isocratic and gradient separation of inorganic and organic anions. In 2001, Pyo and Kim reported the development of capillary ion chromatography using open tubular columns and suppressed conductivity detectors ( J. Korean Chem. Soc. , 2001, Vol. 45, No. 3). According to the above documents, open tubular capillary columns coated with DMEOHA latex particles were used as separation columns. Examples of the suppressor, have been manufactured using a Nafion ^® hollow fiber tubing, the suppressor is used which is chemically reproduced by using an acid solution on the outside.

In the foregoing documents, capillary ion chromatography with a suppressed conductivity detector is performed using a suppressor made of ion exchange capillary tubing. These documents describe the chemical regeneration of the suppressor using an external dilute acid solution. In this type of suppressor, it is possible to have affinity with the capillary separation column by minimizing its useless volume. However, according to the above-mentioned documents, because of the use of chemical regenerants, there is an additional cost for supplying and disposing the chemical regenerants, and the possibility of leakage of the chemical regenerants into the eluent through the ion exchange membrane. As such, the conductivity detection background rises and may adversely affect the sensitivity of some analytes. Accordingly, there is a need for capillary ion chromatography having an easy to use, robust and reliable capillary suppressor.

Summary of the invention

In one embodiment of the invention, the invention provides a flow-through ion exchange packing in a housing comprising a packing inlet and a packing outlet; And a suppressor having an inlet and an outlet, the capillary tubing consisting of a permselective ion exchange membrane, the tubing being at least partially positioned within the ion exchange packing. An apparatus for capillary ion chromatography is provided.

In another embodiment of the invention, the invention provides a suppressor comprising (a) a capillary tubing having an inlet and an outlet and consisting of a selective permeable ion exchange membrane, wherein the capillary tubing is at least partially flow-through housing. Suppressor, characterized in that located within); (b) a flow detector in fluid communication with the capillary tubing; And (c) a circulating conduit leading the aqueous sample liquid recycled from the detector to the outside of the tubing through the flowable housing.

In another embodiment of the invention, the invention provides a suppressor comprising a capillary tubing having an inlet and an outlet and consisting of a selective permeable ion exchange membrane, the tubing being at least partially located in a flowable housing, The outer wall is characterized by including exchangeable ions containing weakly acidic or weakly basic functional groups.

In another embodiment of the present invention, the present invention provides a process for (a) subjecting an aqueous sample stream comprising isolated sample ionic speices, either positively or negatively charged, through capillary tubing consisting of a selective permeable ion exchange membrane. Flowing and transporting a counterion in the eluent, the charge of which is opposite to the sample ion species, from the inner wall of the tubing to the outer wall of the tubing, across the tubing. Wherein said tubing is packed in a flow-through ion exchange packing; And (b) flowing an aqueous regenerant liquid past the tubing through the ion exchange packing to transport counter ions transported to the outer tubing wall to the far side. Provide a method.

In another embodiment of the invention, the invention provides a process for (a) flowing an aqueous sample stream comprising isolated sample ion species, either positively or negatively charged, in a eluent through capillary tubing consisting of a selective permeable ion exchange membrane, and Transporting large ions in the eluent, the charge opposite to the sample ion species, across the tubing from the inner wall of the tubing to the outer wall of the tubing; (b) detecting the separated ionic species exiting the capillary tubing by flowing the liquid sample stream through a detector; And (c) circulating said aqueous sample stream from said detector to said outer tubing wall to carry counterions transported to said outer tubing wall away.

Preferred Embodiments of the Invention

The system of the present invention is useful for the analysis of numerous ionic species. Species to be analyzed are anions or cations. Suitable samples include surface water, and other liquids such as industrial chemical waste, body fluids, beverages, and drinking water. In the use of the term “ion species”, such ionic species include species in ionic form, and molecular components ionized under the conditions of the present invention.

The present invention relates to an ion chromatography apparatus and an ion chromatography method performed on a capillary scale. The ion chromatography system of the present invention comprises (a) a capillary separation column (typically in the form of a chromatography column), (b) a suppressor (effluent exiting the chromatography column is a capillary tube in the suppressor). Tubing of size (through a capillary suppressor), and (c) a detector, typically a conductivity detector (located downstream of the suppressor).

“Capillary tubing” is defined as, but is not limited to, such terms as narrow bore capillary tubing, as commonly used in chemical analysis. As used herein, "capillary tubing" encompasses tubing having dimensions similar to the internal dimensions of capillary tubing according to the prior art. Such capillaries typically have a bore diameter of about 5 to 1,000 μm, more preferably about 10 to 500 μm. The foregoing dimensions generally apply to both the separator column of the present invention and the suppressor capillary tubing of the present invention. One or more capillaries may be joined to form continuous capillary tubing. The capillary flow rate in the capillary tubing is, for example, 0.1 to 50 μl / min.

In addition to the capillary suppressors of the present invention, any known ion chromatography system may be used, for example, as described in US Pat. Nos. 3,897,213, 3,920,397, 3,925,019, and 3,956,559.

In one embodiment of the present invention, the present invention provides a capillary suppressor schematically shown in FIG. According to this embodiment, an eluent generator of the type shown in FIG. 1 of US Pat. No. 6,682,701 is used, but an eluent generator, or other eluent generators other than those shown in the foregoing patents, is used with the capillary ion chromatography system of the present invention. Can also be used together. The operating principle of the eluent generator is described in detail in the aforementioned US patent document. Also shown in FIG. 1 is the regeneration of the solution out of the capillary tubing from the detector, which is described in detail below. For such regeneration in other types of suppressors, reference may be made to the contents of US Pat. No. 5,248,426.

Referring specifically to the embodiment shown in FIG. 1, deionized water (not shown) obtained from the source is pumped by the pump 12 to the high pressure base generator chamber 14 of the base generator 15. The chamber 14 is separated from the low pressure ion source reservoir 16 which contains the source of eluent ions. As shown, the system is an anion analysis system wherein the ions to be supplied to the analyte are cations, such as potassium ions, or sodium ions, lithium ions, or other cations as shown, the ion source reservoir described above. It may be in the form of a base or salt solution, which may be supplied as described in the '701 patent. Substantially, a charged selective permeable membrane barrier or connector 18 provides an ion transport bridge to transport the potassium ions into the base generating chamber 14 while bulk liquid flow. flow can be prevented. The above-described 'for the appropriate membrane, e.g., a film formed of Nafion ^® is possible to see the information contained in the 701 patent literature. The anode 20 (eg platinum) is in electrical communication with the reservoir 16, and the cathode 22 (eg platinum) is disposed at the outlet of the base generating chamber 14. Cation exchange packings, such as resin beds, may be located in base generation chamber 12 as shown in the aforementioned '701 patent document. By performing electrolysis, a base, ie, KOH, is produced in the base generating chamber 14 by providing a reaction as described in the aforementioned '701 patent document. In an electric field to which a current is applied, potassium ions move through an ion exchange connector or an ion exchange membrane and bind with hydroxide ions, thereby forming a KOH eluate. The concentration of KOH eluate formed is proportional to the applied current and inversely proportional to the flow rate of the deionized water carrier stream. Hydrogen is produced at the cathode and can interfere with the analytical process. Therefore, it is usually preferable to use a hydrogen degassing tubing device 26 (see contents described in the '701 patent document) to remove the generated hydrogen gas using a porous membrane.

When the sample is injected into the injector 28, the eluent is transported from the base generator 15 to the ion exchange chromatography separation column 30. For anion analysis, the separation process is carried out using an anion separation medium, typically a packed bed of ion exchange resin in column 30, but with a column having capillary dimensions as described above.

As shown, the effluent flowing out of the capillary anion separation column 30 flows into the inlet 32a of the capillary tubing 32 and is discharged to the outlet 32b through the tubing, thereby detecting the detector 34. Preferably through a conductivity detector. Tubing 32 is contained within a suppressor housing 36, which may have any shape, including tubular or rectangular. The effluent exiting the detector 34 is circulated in the line 38 to the injection port 36a of the housing 36 and then flows out of the tubing 32, preferably in the tubing 32 It flows out in the reverse direction and is discharged to the discharge port 36b.

Capillary tubing 32 consists of a selective permeable ion exchange membrane, preferably a selective permeable ion exchange membrane of the type described in the prior art, such as Nafion ^® , which blocks the bulk liquid flow, while the selected ions (cations in anion analysis) Transport. Thus, the wall of the tubing provides the same function as the membrane suppressor or membrane barrier 18 according to the prior art, which may also be composed of Nafion ^® . The suppressor will be described in more detail below.

In the present invention, in addition to the eluent generator described above, other eluent generators, such as generators for carbonate salts (e.g. potassium carbonate) described in PCT application WO 2004/024302, may be combined with ionized water sources. It is available. At this time, the ion chromatography downstream of the eluent generator is also the same as shown in FIG. In addition, for example, the eluent generator described in US Pat. No. 5,045,204 or US Pat. No. 6,562,628 may be used.

Although the eluent generator used for the anion analysis and the production of cations such as potassium ions has been described, the membrane ion exchange resin and the electrode as described in US Pat. No. 6,682,701 can also be used for cation analysis using the same system. The polarity of can be reversed as appropriate to produce MSA or other anions as eluent.

When using the system of FIG. 1 comprising an eluent generator as described above, the overall ion chromatography, including an analyte separation process, an eluent suppression process, and an analyte detection process, using one or more flow streams of deionized water. It is clear that it can be performed to carry out a graphics separation process.

2 is a view schematically showing a capillary suppressor according to an embodiment of the present invention. Hereinafter, in FIG. 1 and FIG. 2, the same part is described with the same number. As shown, the suppressor housing 36 is a column having a flow-through port, preferably a column formed of a non-conductive (eg plastic) material. Comprises capillary tubing 32 having an inlet 32a and an outlet 32b. The tubing is typically projected into and out of the housing 36 through a liquid tight fitting and protrudes in direct or indirect fluid communication with the outlet of the separation column 30. The outlet 32b of the tubing 32 protrudes through the housing and is connected to the tubing and in fluid communication with the inlet of the flow detector 34.

In anion analysis, the cation exchange capillary tubing is densely embedded in a cation exchange packing 40, preferably a cation exchange resin bed, in direct contact with the tubing. The packing 40 is contained within the housing 36. As shown, separate fluidic connections are used for the stream flowing through the capillary tubing. The source of the flowable aqueous regenerant liquid passes from the inlet 42 in the conduit through the packing 40 and then out of the outlet 44 through a suitable fitting. The solution then enters detector 34 through a conduit. In the embodiment shown in FIG. 1, the water source at the inlet 42 is sampled flowing out of the conductivity detector after detection, flowing through the circulating conduit 38 shown in FIG. 1, as shown in FIG. 1. It is an outflow.

According to one embodiment, the cation exchange capillary tubing 32 is a Nafion ^® membrane made of a material, and a strongly acidic cation exchange membrane of the other form. Typical lengths of the capillary tubing in the suppressor are about 0.1 to 50 cm, preferably 1 to 20 cm. The inner diameter of the capillary tubing is preferably about 0.001 inches to 0.010 inches. According to one embodiment of the invention, the cation exchange resin for ion separation is preferably a strong acid cation exchange resin, such as sulfonated resin in the form of hydronium ions (H ⁺ ).

In this specification, "strongly acidic cation" exchange resins or functional groups are used in the same sense as used in the field of chromatography. For example, Dowex 50W X8 and Amberlite IR 122 are commonly used strongly acidic cation exchange resins. In this type of resin the functional group is generally a strong acid with a pKa value of less than one. Typically, strong acid functional groups include sulfone groups.

As used herein, a "weakly acidic cation" exchange resin or functional group is used in the same sense as used in the field of chromatography. For example, Chelex-100 and Bio-Rex 70, and Amberlite IRC-76 resins are commonly used weakly acidic cation exchange resins. In this type of resin the functional group is generally a weak acid having a pKa value greater than one. Typically, the weakly acidic functional groups include carboxylic acid groups, chlorocarboxylic acid groups, and phosphonic acid groups.

According to one embodiment of the invention, a known cation exchange packing 40 in the form of hydronium may also be used. Although the packing 40 of the preferred form has been described with an ion exchange resin bed, other types of packing, such as ion exchange capacity capable of forming a conducting bridge of cations or anions between the electrodes, It is also possible to use a porous continuous structure having an undesired pressure drop and having a porosity through which a solution can flow. Illustrating this type of structure, a sponge-like, sulfonated crosslinked polystyrene having a porosity of about 10 to 15%, circulating the solution at a flow rate of about 0.1 to 3 mL / min without excessive pressure drop occurs Materials, or porous matrices.

In an unshown embodiment of the invention, the flow rate of the sample liquid stream in the circulation conduit 38 is sufficient to transport ions transported through the walls of the tubing 32, and / or to cool the electrolytic suppressor. If not, an additional source of flowable aqueous liquid (not shown) may be transported through packing 40. In the above case, an additional source of aqueous liquid may comprise a stream of water (eg, deionized water), which is pumped into the suppressor and merged into a single stream with water in the circulation conduit, or packing Via 40 can be transported in a separate conduit. As in the case of a suppressor comprising a circulation conduit according to the prior art, it is preferred to introduce water through the packing outside the tubing, in the reverse direction of the flow direction in the tubing.

When the aqueous effluent flowing out of the conductivity detector circulates and is transported through the packing 40, as long as there is water in a continuous flow to remove KOH generated in the hydrolysis reaction of the weakly acidic resin in potassium form, The suppressor may continue to play. Depending on the chemical properties of the functional groups of the resin, the reaction rate of the hydrolysis reaction is a limiting factor that determines the suppression capacity of the device in relation to the amount of KOH eluent flowing into the suppressor. Can be The use of a second stream of deionized water passing through the resin bed of the suppressor, which can be operated at a flow rate higher than the flow rate in the separation process, is preferred because the suppression capacity can be improved.

In the case of anion analysis, a base eluent (e.g., KOH) enters the capillary tubing, so that the potassium ions (K ⁺ ) are exchanged for hydronium ions (H ⁺ ) in the capillary wall according to the following reaction Use capillary tubing:

R-SO ₃ H + KOH (eluent) → R SO ₃ K + H ₂ O (suppressed eluent) (One)

R-SO ₃ H + KX (analyte) → R SO ₃ K + HX (Suppressed Analyte) (2).

Wherein R represents an ion exchange surface on the capillary. Because the cation exchange capillary is in direct physical contact with a bed of cation exchange resin, the K ⁺ ions originally exchanged to the wall of the cation exchange capillary continue to be exchanged for H ⁺ ions in the resin beads directly adjacent the wall. This exchange process is then carried out between the resin beads, which are not in direct physical contact with the ion exchange capillary, but located further away from the capillary tubing. In the exchange process described above, the cation exchange resin beads become a source of regenerant ions (ie, H ⁺ ions) to regenerate the cation exchange capillary tubing. In the suppression process, the cation exchange beads around the cation exchange capillary are mainly in the form of potassium, and the flux of introduction of hydronium ions into the cation exchange capillary is reduced to a level at which the introduced KOH eluent cannot be neutralized. Continued until

The preferred suppression capacity of the device at a given eluent concentration and flow rate is the length of the capillary, the flow profile of the eluent within the capillary, the ion exchange capacity of the resin, the particle size of the resin, the amount of resin around the capillary And many factors, including the geometry of the resin bed and the like. For example, the cation exchange capillary tubing may be constructed in a geometric pattern to form a flow path of the eluent passing through the capillary in a slow flow path, thereby increasing the contact between the capillary wall and the eluent, thereby providing the device. Can increase the suppression capacity. According to another embodiment, the inner opening of the cation exchange capillary is filled with an inert material or cation exchange monofilament to reduce the dead volume of the capillary suppressor while increasing the contact between the capillary wall and the eluent, The suppression capacity of the device can be increased. Once the effective suppression capacity of the suppressor has been consumed, the entire resin bed can be returned to the hydronium form by regenerating the resin bed of the device off-line using an external source of acid. By flowing water at a constant flow rate to facilitate potassium / hydronium exchange between the ion exchange sites, the effective suppression capacity of the device can be increased. The capillary ion chromatography system shown in FIG. 1 can circulate and transport the aqueous effluent from the conductivity detector through the resin bed of the capillary suppressor. According to another embodiment, by supplying a separate stream of deionized water through the resin bed of the suppressor, the same effects as described above can be obtained.

As shown in FIG. 2, the capillary tubing 32 may be in the form of a coil to flow in a serpentine path. Depending on the length of the suppressor capillary tubing desired to achieve suppression, the tubing may have a straight or coiled form, or any desired form. Typically, due to the resistance of the flow, it may not have the shape bent at right angles, as shown.

According to another embodiment of the present invention, the suppressor of FIG. 2 may be used except that the cation exchange resin packing 40 around the capillary tubing 32 includes weakly acidic functional groups in addition to the strongly acidic functional groups. H ⁺ ions combined with cation exchange resin particles around the capillary 32 act as a source of regenerant ions (ie, H ⁺ ions) and promote the above-mentioned suppression action. K ⁺ ions originally exchanged to the wall of the capillary continue to be exchanged for H ⁺ ions in the resin beads directly adjacent to the wall. This exchange process is continued in the resin beads which are not in direct physical contact with the wall of the tubing 32 but located further away from the wall. At the same time, the weakly acidic resin in the form of potassium can be hydrolyzed according to the following scheme:

.

.

If there is a constant flow of water through the resin bed, the KOH produced in the hydrolysis reaction of the resin can be transported from the resin bed. The regenerated resin can then be used again in the suppression process according to the following scheme:

.

.

The preferred suppression capacity of the device at a given eluent concentration and flow rate is the length of the capillary, the flow profile of the eluent within the capillary, the ion exchange capacity of the resin, the particle size of the resin, the amount of resin around the capillary And many factors, including the geometry of the resin bed and the like. In this embodiment, the resin bed may be made of a mixture of a strong acid cation exchange resin and a weak acid cation exchange resin. The aforementioned regeneration can be carried out in a homogeneous or heterogeneous mixture of these two different types of resins. In the above resin mixture, the weakly acidic cation exchange resin can be continuously regenerated by hydrolysis as described above. Therefore, according to the present invention, it is preferable because continuous operation is possible without performing offline regeneration using an external acid solution.

In anion analysis, as another embodiment of the capillary tubing 32 used in the suppressor of the present invention, the capillary tubing shown schematically in FIG. 3 is provided. In this embodiment the cation exchange capillary comprises both strongly acidic and weakly acidic functional groups. 3 is a schematic cross-sectional view of a cation exchange capillary tube used in this embodiment. Usually the inner wall of the cation exchange capillary is made of an ion exchange material containing strongly acidic functional groups. The outer wall of the capillary contains weakly acidic functional groups (e.g., weakly acidic functional groups bonded to the capillary by grafting the linear polymer containing the weakly acidic functional groups and the strongly acidic capillary tubing). Techniques suitable for modifying the capillary polymer surface by graft polymerization of one of the monomers derived from the active site produced on the solid polymer surface are well known (see, for example, Encyclopedia of Polymer Science and Engineering , Supplement Vol. ^{2 nd edition, John Wiley & Sons} (1989) 678, Macromolecules, Vol. 9, (1976), 754, and Macromolecules, Vol. 12, (1979 ), see 1222). The most commonly used technique is the γ-radiation technique, which generates surface radicals using a radiation source, such as a ⁶⁰ Co source, but uses free radical sites, using thermal, photochemical, plasma, and wet chemical methods. The reaction may be initiated by introducing. The monomer may be present in the gas phase, liquid phase, or pure liquid phase. By modifying the ion exchange capillary using the surface graft polymerization technique described above, weakly acidic functional groups can be present on the outer wall of the capillary.

When the KOH eluent enters the capillary tubing, potassium ions (K ⁺ ) are exchanged for hydronium ions (H ⁺ ) at the inner wall of the capillary. Then, the K ⁺ ions originally exchanged to the inner wall of the cation exchange capillary continue to be exchanged for H ⁺ ions on the weakly acidic functional groups bound to the outer wall of the capillary. As described above, the weakly acidic functional groups in the form of potassium can be hydrolyzed according to the following scheme:

.

.

If there is a constant stream of water flowing out of the cation exchange capillary 32, the KOH produced in the hydrolysis reaction described above may be transported out of the plastic housing 36. In this manner of operation, the suppressor can continue to be regenerated as long as there is a continuous flow of water to remove regenerated KOH. The aqueous effluent flowing out of the conductivity detector 34 may be circulated and transported and out of the cation exchange capillary. The suppression capacity may be enhanced by using a second stream of deionized water at a flow rate faster than the flow rate used in the separation process. In an embodiment of the invention, the weakly acidic functional groups bound to the outer wall of the capillary tubing can continue to be regenerated by electrolysis as described above. Therefore, according to the present invention, it is preferable because continuous operation is possible without performing offline regeneration using an external acid solution.

4 is a view showing an electrolytic capillary suppressor for anion analysis that can be continuously operated according to an embodiment of the present invention. In FIG. 2 and FIG. 4, the same parts are denoted by the same numbers. As in the embodiment of FIG. 2, in this embodiment the capillary anion suppressor is a cation exchange capillary tubing densely embedded inside a bed of cation exchange resin 40 housed in a plastic column housing 32 having flowable ports. And (32). The inlet of the resin bed is equipped with a flow-through anode 50, for example a perforated Pt anode, and the outlet of the resin bed is equipped with a flow-through cathode 52, for example a perforated Pt cathode. have. These two electrodes are preferably in direct contact with the packing 40 of the type described above. The cation exchange capillary tubing may be made of the aforementioned material having the dimensions as described above. In operation of this type of electrolytic capillary suppressor, the resin bed continues to be regenerated by hydronium ions produced by the electrolysis of water at the anode of the device. For the principle and description of continuous electrolytic suppression, reference may be made to the contents described in US Pat. No. 6,468,804. As shown in FIG. 1, water used for electrolysis may be supplied from an aqueous effluent (ie, a pressed eluent) circulated from the conductivity detector. In addition, as described above, in place of or in addition to the circulation stream, deionized water of a separate stream may be fed through the resin bed.

According to another embodiment of the electrolytic capillary suppressor (not shown), the operation of the suppressor is such that the water used for the electrolysis reaction is located near the center of the packing 40, for example, in the lower center of FIG. 4. Same as in the embodiment shown in FIG. 4, except for transport to the resin bed through a liquid connection port. In this configuration, water is split into two streams (the first stream exiting the anode 50 of the device, and the second stream passing through the device's cathode 52) and then discharged from the device. One advantage according to this embodiment is that the performance of the suppressor is achieved by venting the gas produced during the electrolysis reaction (ie oxygen at the anode, hydrogen at the cathode) out of the device without passing it through the resin bed. Is to improve it.

5 is a diagram illustrating an electrolytic capillary suppressor for anion analysis according to another embodiment of the present invention. In this embodiment, the suppressor 60 includes three chambers, and the central chamber includes an ion exchange packing 40 in which capillary tubing 32 is embedded, as shown. In the system according to the present embodiment, the same parts as those in FIGS. 1 to 4 are denoted by the same numbers. As in the apparatus of FIG. 1, the sample containing effluent flowing out of the chromatography column flows into the inlet 32a of the capillary tubing, and the liquid exiting the capillary tubing 32b enters the detector. The water source 62 may be circulated from the detector and / or other sources of aqueous liquids. The fundamental difference between the embodiment of FIG. 4 and the embodiment of FIG. 5 is the presence or absence of one or two chambers that do not contact the flow through the packing 40. In this embodiment, the solution passing through the packing 40 is introduced into the electrode chamber 64 in which the anode 52 is disposed. As shown, the electrode chamber 62 and the packing 40 are separated by an optional selective permeable barrier 66. The solution exiting the electrode chamber 64 may be circulated in the conduit 66 through the cathode chamber 68 at the cathode 60, which may be separated from the packing 40 by an optional barrier 70. have. The use of the separate electrode chambers with barriers 68 and 70, or the separate electrode chambers without barriers, for suppressing the filled resin bed is described in the embodiment of FIG. 2 of US Pat. No. 6,027,643. See. Described the fundamental difference between the embodiment of the present invention and the embodiment of the '643 patent, according to the present invention, the flow of the sample containing the eluent through the resin bed passes through the capillary tubing in the resin bed, According to the 643 patent, the flow is in contact with the tubing. Conventional principles for the electrolysis operation are the same as in the embodiment of FIGS. 4 and 5 except for separating the flowable resin bed and the electrodes. The aqueous stream is preferably transported through packing 40 to the anode and cathode chambers used in the electrolysis reaction. By introducing water through the packing 40, heat generated during the operation of the electrolytic capillary suppressor may be removed.

In the above-described embodiments of electrolytic capillary ion suppression, the suppressor can be operated continuously or intermittently. In the case of intermittent operation of the suppressor, once the effective suppression capacity is consumed, the resin bed is electrolytically produced and potassium ions are removed so that the packing can be returned to hydronium form in subsequent cycles. The number of times of performing such intermittent suppression may depend on the dimensions of the apparatus and the inflow rate of the eluent.

In order to continuously operate the suppressor without having to regenerate the packing offline, the total ion exchange capacity of the packing can be selected to correspond to the capacity required for a given eluent stream. For example, in an electrolytic operation such as in FIG. 4, the total ion exchange capacity of the packing is at least 10 times, as high as 10,000 to 100,000 times, or more than the ion exchange capacity of the capillary tubing.

By appropriately inverting the polarity of the packing electrode and the membrane, the capillary suppressor according to the prior art can be used for suppressing the acid eluent in cation analysis.

1 to 5 are schematic diagrams showing embodiments of the present invention.

6 to 12 are diagrams showing the results of experiments using the method and apparatus according to the embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to Examples, but the present invention is not limited to the following Examples.

Example  1: at capillary chromatography flow rate KOH Eluent Electrolytic  produce

This example relates to the electrolytic generation of KOH solutions at capillary chromatography flow rates. A modified Dionex P680 pump (manufactured by Dionex Corporation, Sunnyvale, Calif.) Was used to transport the deionized water stream at a flow rate of 10 μl / min. Deionized water was first passed through an ATC-HC column and a CTC-1 column to remove ionic impurities and transported to a KOH eluent generator to produce a KOH solution. The KOH eluent generator is manufactured by modifying the Dionex EGC-KOH cartridge (P / N 058900). A Keithley Model 220 Programmable Current Source (Keithely Instruments, Inc., Cleveland, Ohio) was used to apply direct current to the anode and cathode of the KOH eluent generator. The conductivity of the resulting KOH solution was monitored using a Dionex ED50A conductivity detector equipped with a modified flow conducting cell. Device control, data collection, and processing were performed using a Dionex Chromeleon 6.5 computer workstation.

FIG. 6 shows the results of overlaying eight conductivity profiles measured on an electrolytically produced KOH eluent at a flow rate of 10 μl / min. In the present embodiment, the direct current applied to the eluent generator was changed in steps of 0.321 kV from 0 kV to 3.21 kPa in steps, thereby generating KOH eluent at a concentration of 20 mM from 0 mM to 200 mM. From the results shown in FIG. 6, it can be seen that the production of KOH solution is reproducible over a wide range of concentrations at capillary flow rates.

Example  2: capillary tube of conventional anion IC  When separated, dendritic ( resin phase A) regenerative capillary anion Suppressor  Usage

This example relates to the use of a dendritic regenerated capillary anion suppressor of the type shown in FIG. 2 in conventional capillary IC separation of anions. The capillary IC system used in this experiment was manufactured according to the scheme shown in FIG. A modified Dionex P680 pump (manufactured by Dionex Corporation, Sunnyvale, Calif.) Was used to transport the deionized water stream at a flow rate of 12 μl / min. Deionized water was first passed through a Dionex ATC-HC column and a CTC-1 column to remove ionic impurities and was prepared by modifying a KOH eluent generator (Dionex EGC-KOH cartridge (P / N 058900) to produce a KOH solution. ), A KOH eluent was produced. A Keithley Model 220 Programmable Current Source (Keithely Instruments, Inc., Cleveland, Ohio) was used to apply direct current to the anode and cathode of the KOH eluent generator. A high pressure degas unit was connected to the outlet of the KOH eluent generator to remove hydrogen gas generated during the electrolytic generation process of the eluent. Samples were injected using a Rheodyne 6-port PEEK high pressure injection valve (Cotta, CA, USA). In PEEK tubing with a length of 250 mm, an internal diameter of 380 μm, and an outer diameter (OD) of 1/16 inch, a surface-functionalized anion exchange resin (owned by Dionex) ), To prepare a capillary anion separation column. A Dionex ED50A conductivity detector equipped with a modified flow conducting cell was used. Device control, data collection, and processing were performed using a Dionex Chromeleon 6.5 computer workstation.

In this embodiment, a capillary suppressor was manufactured according to the basic diagram shown in FIG. 2. In a bed of 8% crosslinked 20 μm sulfonated styrene divinylbenzene resin beads (Dionex Corporation), housed inside a PEEK column (ID 9 mm × 150 mm in length) with two flowable liquid connection ports, 15 cm in length a Nafion ^® cation exchange capillary tubing (0.004 ID inchi × OD 0.010 inches) was filled. In addition, it installs the equipment for providing a separate fluid connector body in the Nafion ^® cation exchange capillary tubing. The suppressed effluent flowing out of the conductive cell was transported at a rate of 12 μl / min through the resin bed of the suppressor.

FIG. 7 shows the results of the separation of seven conventional anions (fluoride, chloride, bromide, nitrate, nitrate, sulfate, and phosphate) obtained using the system described above. The concentration of KOH eluate was varied from 38 mM to 200 mM. When the concentration of KOH eluent was 38 mM, complete resolution was obtained for all seven anions. As expected, co-elution of anions was observed at high concentrations of KOH. From the results shown in FIG. 7, it is possible to successfully suppress KOH eluents of different concentrations in the case of separation of conventional anions by capillary IC using the dendritic regenerative anion suppressor of the type shown in FIG. 2. You can check it. More specifically, it can be seen from the results of FIG. 7 that an anion separation process using one flow stream of deionized water is possible using the capillary IC system shown in FIG. 1.

Example  3. in anion analysis, KOH Eluent At the time of suppression  Dendritic regeneration capillary Suppressor  Operation

This example shows the use of a dendritic regenerated capillary anion suppressor of the type shown in FIG. 2 for use in capillary IC separation of conventional anions. The capillary ion chromatography system used in this example is the same as the system used in Example 2, except that different dendritic regenerated capillary anion suppressors were used. In this example, the capillary suppressor was manufactured according to the basic scheme shown in FIG. 2. 2 were buried in the resin bed contained in the interior of circulation-type PEEK column having a fluid connection port (ID 9 ㎜ × length 150 ㎜), length 15 ㎝ of Nafion ^® cation exchange capillary tubing (ID 0.004 inchi × OD 0.010 inches). In addition, the equipment was installed so that separate fluid connections to the Nafion ^® cation exchange capillary tubing. The suppressor resin bed comprises 95% (w / w) of 20% sulfonated styrene divinylbenzene resin (Dionex Corporation) of 8% crosslinked and 200-400 mesh Chelex-100 resin (Bio-Rad Laboratories, USA). Manufactured by Hercules, Calif.) 5% (w / w). The Chelex-100 resin is a cation exchange group having a weakly acidic iminodiacetate functional group. The pressed effluent, which flowed out of the conductive cell, was transported at a rate of 12 μl / min through the resin bed of the suppressor.

In this example, the separation of seven anions (fluoride, chloride, bromide, nitrite, nitrate, sulphate, and phosphate) on a capillary anion separation column as described in Example 2 was carried out at least 400 successively (each Run time per session: 20 minutes), and then the long-term performance of the capillary suppressor was monitored. 100 mM KOH was used as the eluent. As shown in Fig. 8, when using the suppressor, a stable suppressing background value was obtained for at least 380 performances. At the 390th separation, a slightly unstable suppressing background was observed. At 400 times, a noticeable unstable suppression background value was observed. From the results shown in FIG. 8, it can be estimated that the dendritic regeneration capillary anion suppressor of the type shown in FIG. 2 can fully function for a longer time in capillary IC separation of conventional anions. In addition, it can be seen from the results shown in FIG. 8 that the capillary IC system shown in FIG. 1 can be used to perform anion separation process using one flow stream of deionized water.

Example 4 Cation Exchange Between Sulfonated Resin Beads in Hydronium Form and Sulfonated Resin Beads in Potassium Form

This example shows the results of visual observation of cation exchange between hydronium sulfonated resin beads and potassium form sulfonated resin beads. In this example, a capillary suppressor was manufactured according to the basic diagram shown in FIG. 2. I.D. 0.004 inch x O.D. 0.010 inch grafted and sulfonated, 15 cm long TFE capillary tubing (Dionex Corporation) from 200 to 400 mesh AG 50 W × 16 resin (sulfonated cation exchanger, available from Bio-Rad Laboratories, Hercul, CA, USA Buried in Leeds). The resin bed was charged to a clear glass column (I.D. 6 mm × 250 mm long) (obtained from Bio-Chem Valve, Inc., Bunton, NJ). The 200-400 mesh AG 50 W × 16 resin was uniformly coated with a small amount of cationic dye quinaldine red, and then the resin bed was mounted in the glass column. The coated resin appeared gold when in the hydrogen form. When the coated resin is in the form of potassium, the color changes to magenta. Therefore, using the color change of the resin, cation exchange between the sulfonated resin beads in the form of hydronium and the sulfonated resin beads in the form of potassium can be visually confirmed. Using the system described in Example 2, the action of this capillary suppressor was evaluated. The suppressor was used continuously to suppress 20 mM KOH at a flow rate of 10 μl / min. In this example, the pressed eluate discharged from the conductive cell was transported to waste. A second stream of deionized water was pumped at a flow rate of 0.25 mL / min and passed through the bed.

Six hours after the operation, a slight color change was observed in the resin around the inlet end of the sulfonated TFE capillary in the suppressor. After 72 hours of operation, a significant color change was observed in the resin bed present at the inlet end of the suppressor. At 144 hours after the operation, a distinct band of resin with magenta color was observed in the resin bed at the inlet end of the suppressor. From these observations, K ⁺ ions originally exchanged on the cation exchange capillary wall continue to be exchanged with H ⁺ ions in the resin beads directly adjacent to the wall, and subsequently this exchange process is performed physically with the cation exchange capillary. It can be seen that there is no direct contact and can continue to occur between resin beads that are located at a location farther from the capillary tubing.

In another experiment, one drop of AG 50W × 16 resin (potassium form, magenta) coated with quinaldine red was added to a bed of AG 50W × 16 resin (hydronium form, gold) coated with quinaldine red in a beaker. Put in. After 2 hours, the color intensity of the magenta resin noticeably decreased. After 72 hours the color of the added magenta resin faded out. After 192 hours, the added resin was hardly distinguished from the rest of the resin bed, thereby confirming that the added resin was converted into hydronium form.

Example 5 Capillary IC Separation of Anionic Analyte Using Electrolytically Generated KOH Eluent, and Depressed Detected Conductivity Using Electrolytic Capillary Suppressor of the Type shown in FIG.

This embodiment relates to the use of an electrolytic capillary anion suppressor of the type shown in FIG. 5 for use in conventional capillary IC separation of anions. The capillary ion chromatography system used in this example is similar to that used in Example 2, except that an electrolytic capillary anion suppressor was used in the system. In this example, an electrolytic capillary suppressor was prepared. The capillary anion suppressor consists of three PEEK chambers. The effluent chamber comprises a cation exchange capillary tubing densely embedded within a bed of cation exchange resin (ID 6-8 mm × length 10-25 mm). A separate fluid connection was installed in the cation exchange capillary tubing in the resin bed. The electrolyte in the production of capillary suppressor, ID 0.004 inchi × OD 0.010 inches and a length of 15 ㎝ the grafted and sulfonated TFE capillary tubing (Dionex Corporation), or of 15 ㎝ length of Nafion ^® cation exchange capillary tubing (ID 0.004 Inch x OD 0.010 inch). Cathode regenerator chambers and anode regenerator chambers using grafted and sulfonated TFE cation exchange ion exchange membranes (Dionex Corporation) are physically separated by an eluent chamber. The cathode chamber comprises a perforated Pt cathode and the anode chamber comprises a perforated Pt anode. The two electrode chambers have two liquid connection ports (inlet and outlet). In this example, the pressed eluate discharged from the conductive cell was transported to the waste liquid. A second stream of deionized water was pumped to the resin bed in the eluent chamber and then to the anode regenerator chamber and the cathode regenerator chamber at a flow rate of 0.1 to 0.25 mL / min. A 20 mA direct current was supplied to the electrolytic capillary suppressor using a Dionex ED50A module. Using a Dionex EG40 eluent generator control module, direct current was supplied to a KOH eluent regeneration cartridge to produce a KOH eluent for use in ion chromatography separation of anions.

FIG. 9 shows the suppressed conductivity background value obtained using the system when changing the concentration of KOH eluent from 20 mM to 200 mM at a rate of 10 μl / min. As a result, it can be seen that the electrolytic capillary suppressor can effectively suppress KOH at various concentrations.

FIG. 10 shows 20 consecutive separations of seven conventional anions (fluoride, chloride, bromide, nitrite, nitrate, sulfate, and phosphate) in a capillary column packed with a latex aggregated anion exchanger (Dionex Corporation). It is a figure which shows the result superimposed. The separation process was carried out using 38 mM KOH at a flow rate of 10 μl / min. As a result, analyte retention percent (%) relative standard deviation (RDS) ranges from 0.028% (sulfate) to 0.10% (phosphate) and analyte peak area ratio RSD of 0.033% ( Nitrite) to 0.58% (phosphate), it can be seen that high reproducibility can be obtained in the separation of target anions.

11 shows 11 conventional anions (fluoride, chlorite, bromate, chloride, nitrite, chlorate, bromide, nitrate, in a capillary column packed with anion exchanger (Dionex Corporation) having functional groups on its surface). Carbonate, sulphate, and phosphate) is a view showing that the results of 10 consecutive separations are overlapped. The separation process was performed at a flow rate of 10 μl / min, with a gradient of KOH eluent from 10 mM to 25 mM. As a result, the analyte retention rate (%) relative standard deviation (RDS) ranges from 0.072% (phosphate) to 0.19% (knightite), indicating that high reproducibility can be obtained in separation of the target anion. .

From the above results, it can be seen that by using the capillary IC system according to the present invention, only deionized water can be used as a carrier stream to provide a reliable analysis result of the target anionic analyte.

Example 6 Capillary IC Separation of Cationic Analyte Using Electrolytically Generated MSA Eluent, and Depressed Detected Conductivity Using Electrolytic Capillary Suppressor of the Type shown in FIG. 5

This embodiment relates to the use of an electrolytic capillary cation suppressor of the type shown in FIG. 5 for use in capillary IC separation of conventional cations. The basic system components of the capillary ion chromatography system used in this example are for cation analysis, similar to those shown in FIG. A Dionex EGC-MSA cartridge (P / N 058902) was modified to prepare a methanesulfonic acid (MSA) eluent generator. Using a Keithley Model 220 Programmable Current Source (Keithely Instruments, Inc., Cleveland, Ohio), a direct current is supplied to the MSA eluate production cartridge to generate an MSA eluate for use in the separation of cations by ion chromatography. It was.

The electrolytic capillary suppressor was prepared according to the basic schematic shown in FIG. 5. The capillary anion suppressor consists of three PEEK chambers. The eluent chamber is a 15 cm long graft and aminated TFE capillary tubing (ID 0.004 inch x OD 0.010 inch, Dionex Corporation) densely embedded inside a strong basic anion exchange resin bed (ID 6 mm x 20 mm length). Include. A separate fluid connection was installed in the cation exchange capillary tubing in the resin bed. Cathode regenerator chambers and anode regenerator chambers using grafted and aminated TFE cation exchange ion exchange membranes (Dionex Corporation) are physically separated by the eluent chamber. The cathode chamber comprises a perforated Pt cathode and the anode chamber comprises a perforated Pt anode. The two electrode chambers have two liquid connection ports (inlet and outlet). In this example, the pressed eluate discharged from the conductive cell was transported to the waste liquid. A second stream of deionized water was pumped into the resin bed in the eluent chamber and then pumped into the cathode regenerator chamber and the anode regenerator chamber at a flow rate of 0.2 mL / min. 15-20 mA of direct current was supplied to the electrolytic capillary suppressor using the Dionex SC20 suppressor control module.

FIG. 12 shows the results of separating six conventional cations (lithium, sodium, ammonium, potassium, magnesium, and calcium) from a capillary column packed with a cation exchanger (Dionex Corporation) having functional groups on its surface. . The separation process was carried out using 8 mM MSA at a flow rate of 10 μl / min. As a result, all cationic analytes could be separated with good resolution. Thus, it can be seen that by using the capillary IC system according to the present invention, only deionized water can be used as the carrier stream to provide reliable analysis results of the target cationic analyte.

Claims (49)

A device for capillary ion chromatography, (a) flow-through ion exchange packing in a housing comprising a packing inlet and a packing outlet; And a suppressor having an inlet and an outlet, the capillary tubing consisting of a permselective ion exchange membrane; The tubing is located at least partially within the ion exchange packing. Capillary ion chromatography apparatus, characterized in that. The method of claim 1, (b) a source of fluid aqueous regenerant liquid in fluid communication with said packing inlet. The method of claim 2, (c) a capillary chromatography column in fluid communication with said capillary tubing inlet. The method of claim 3, (d) a flow-through detector in fluid communication with the capillary tubing outlet. The method of claim 4, wherein The device is (e) a recycle conduit for directing circulated aqueous liquid from said detector to said ion exchange packing, As such, the aqueous regenerant liquid source comprises the circulated aqueous liquid. Device characterized in that. The method of claim 5, The aqueous liquid source further comprises an additional source of flowable aqueous liquid in addition to the circulated aqueous liquid. The method of claim 1, At least a portion of the capillary tubing is in direct contact with the packing. The method of claim 1, Wherein said packing comprises a packed bed of ion exchange particles. The method of claim 1, The ion exchange packing, An apparatus comprising a substrate having exchangeable ions comprising weakly acidic or weakly basic functional groups. The method of claim 9, The ion exchange packing, And further comprising a substrate having exchangeable ions comprising a strongly acidic or strongly basic functional group. The method of claim 1, Wherein the outer wall of the capillary tubing comprises exchangeable ions comprising weakly acidic or weakly basic functional groups. The method of claim 11, Wherein the inner wall of the capillary tubing comprises exchangeable ions comprising a strongly acidic or strongly basic functional group. The method of claim 11, Wherein the weakly acidic or weakly basic functional group comprises a moiety on a polymer grafted to the outer wall of the tubing. The method of claim 1, and (b) first and second electrodes spaced apart from each other on opposite sides of the ion exchange packing. The method of claim 14, And the packing injection hole is positioned between the first electrode and the second electrode. The method of claim 14, Wherein the first electrode is located in an electrode chamber. The method of claim 16, And the second electrode is located in an electrode chamber. The method of claim 16, and (c) a selective permeable ion exchange barrier between the first electrode and the packing. (a) a suppressor comprising a capillary tubing having an inlet and an outlet and consisting of a selective permeable ion exchange membrane, said capillary tubing being at least partially located in a flow-through housing; (b) a flow detector in fluid communication with the capillary tubing; And (c) a circulating conduit directing the recycled aqueous sample liquid from the detector out of the tubing through the flowable housing Capillary ion chromatography apparatus comprising a. The method of claim 19, And in addition to said aqueous liquid sample, an additional source of aqueous liquid flowing through said housing. The method of claim 19, Wherein the outer wall of the capillary tubing comprises exchangeable ions comprising weakly acidic or weakly basic functional groups. The method of claim 19, Wherein the inner wall of the capillary tubing comprises exchangeable ions comprising a strongly acidic or strongly basic functional group. The method of claim 19, Wherein said weakly acidic or weakly basic functional group comprises a polymer phase moiety graft polymerized on an outer wall of said tubing. The method of claim 19, (a) a capillary chromatography column in fluid communication with the capillary inlet. (a) a suppressor comprising a capillary tubing having an inlet and an outlet and consisting of a selective permeable ion exchange membrane, The tubing is located at least partially within the flowable housing, The outer wall of the capillary tubing includes exchangeable ions containing weakly acidic or weakly basic functional groups. Capillary ion chromatography apparatus, characterized in that. The method of claim 25, Wherein the inner wall of the capillary tubing comprises exchangeable ions comprising a strongly acidic or strongly basic functional group. The method of claim 25, Wherein said weakly acidic or weakly basic functional group comprises a polymer phase moiety graft polymerized on an outer wall of said tubing. The method of claim 25, (b) a capillary chromatography column in fluid communication with the capillary tubing inlet. The method of claim 25, (c) a flow detector further in fluid communication with the capillary tubing outlet. The method of claim 25, and (d) a circulating conduit for introducing from said detector a circulated aqueous liquid into said ion exchange packing. (a) Flowing an aqueous sample stream comprising isolated sample ionic speices, either positively or negatively charged in the eluent, through capillary tubing consisting of a selective permeable ion exchange membrane, the opposite of the sample ion species. Transporting a counterion in the eluent of positive charge across the tubing from the inner wall of the tubing to the outer wall of the tubing, the tubing in a flow-through ion exchange packing. A transportation step characterized in that it is packed; And (b) flowing an aqueous regenerant liquid past the outside of the tubing and through the ion exchange packing to transport counter ions transported to the outer tubing wall away Method of performing capillary ion chromatography comprising a. The method of claim 31, wherein (c) prior to step (a), further comprising separating the ionic species by chromatography in a capillary chromatography column. The method of claim 31, wherein (d) detecting the separated ionic species by flowing the liquid sample stream through a detector. The method of claim 33, wherein (e) circulating the aqueous sample stream to the ion exchange packing, And the regenerant liquid comprises the circulated sample stream. The method of claim 34, wherein (f) in addition to the circulated liquid stream, flowing a second aqueous liquid stream past the outside of the tubing. The method of claim 31, wherein Wherein said packing comprises a packed bed of ion exchange particles. The method of claim 31, wherein Wherein said ion exchange packing comprises a substrate having ions comprising weakly acidic or weakly basic functional groups. The method of claim 31, wherein Wherein said ion exchange packing further comprises a substrate having exchangeable ions comprising a strongly acidic or strongly basic functional group. The method of claim 31, wherein Wherein the outer wall of the capillary tubing comprises exchangeable ions comprising weakly acidic or weakly basic functional groups. The method of claim 31, wherein The inner wall of the capillary tubing comprises exchangeable ions comprising a strongly acidic or strongly basic functional group. The method of claim 31, wherein during (a) and (b), applying a potential across the ion exchange packing. (a) flowing an aqueous sample stream comprising isolated sample ion species, either positively or negatively charged, through a capillary tubing consisting of a selective permeable ion exchange membrane, the eluent being a charge opposite to the sample ion species. Transporting large ions of the ions across the tubing from an inner wall of the tubing to an outer wall of the tubing; (b) detecting the separated ionic species exiting the capillary tubing by flowing the liquid sample stream through a detector; And (c) circulating the aqueous sample stream from the detector to the outer tubing wall for carrying counterions transported to the outer tubing wall away Method of performing capillary ion chromatography comprising a. The method of claim 42, wherein (d) prior to step (a), further comprising separating the ionic species by chromatography in a capillary chromatography column. The method of claim 42, wherein The tubing is filled in a flow-type ion exchange packing, Transporting large ions in the eluent, the charge opposite to the sample ion species, across the tubing from the inner wall of the tubing to the outer wall of the tubing. The method of claim 42, wherein Wherein said packing comprises a packed bed of ion exchange particles. The method of claim 42, wherein Wherein said ion exchange packing comprises a substrate having ions comprising weakly acidic or weakly basic functional groups. The method of claim 42, wherein Wherein said ion exchange packing further comprises a substrate having exchangeable ions comprising a strongly acidic or strongly basic functional group. The method of claim 42, wherein Wherein the outer wall of the capillary tubing comprises exchangeable ions comprising weakly acidic or weakly basic functional groups. The method of claim 44, during (a) and (b), applying a potential across the ion exchange packing.

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